LP-Research specializes in the development and production of life-science and research equipment. Our first development is the LP Motion Sensor (LPMS). Please browse this site to get more information about us and our products:
Lin has designed a very nice holder for the LPMS-C. The basic idea is to separate the main sensor unit and the part that is used to fix the sensor to an object. This makes the possible ways to fix the sensor to an object or person more flexible. See the sketch below to get an idea. Once the sensor is “clipped-in” (by slightly pulling back the holding tooth) it is fastened to the holder. By pulling back the tooth again, the sensor can be easily removed.
The clip-in base to fix the sensor to an object using screws etc.
Hooray! We shipped our first official product! The (hopefully) happy customer is the University of Catania, Italy. Over the next few month we will work together with them, to get feddback on the use of the sensor and to gradually improve the product. This is just the start, in the meantime other orders have come in, so we need to be quick to deliver more sensors.
LPMS-C comes packaged with a sensor holder, cables and a CD containing software and manual.
We ordered some stickers and here they are:
The stickers have arrived!
Beautiful aren’t they 
Neda Firfova (Her portfolio: http://www.nedafirfova.com/) was so nice to design a new logo for us. We haven’t really had time to publish it properly, but here are the drafts. We are really excited about the chance to work together with Neda on this. Her style is supreme!
Some logo ideas
Some more logo ideas
Finally we are ready to show somw progress of the sensor development. Below you can see the new design and a few designs of the case of the Bluetooth version of the sensor (LPMS-B). Actually these have been ready for quite some time, but we were just to busy with finishing the firmware etc. to show them around.
For this image we made half of the case transparent, so you can see the sensor mainboard and the battery inside. Using this larger battery, the size of the sensor has become bigger than the initial prototypes, but the continuous runtime is up to 10 hours. We are planning on producing differently sized cases for different applications, requiring different battery runtimes.
Please note that this 3D print here does not show the final material that we are going to use for the case. The final version will probably be blue and made of non-transparent or semi-transparent plastic.
If the LPMS is operated in an environment with a partially distorted (non-homogeneous) earth magnetic field, there is the possibility of the orientation readings becoming inaccurate due to invalid data from the magnetometer unit. To prevent this we have extended our sensor fusion algorithm to detect such field distortion and automatically switch to operation without magnetometer. The switching between the two states happens seamlessly (without orientation jump) and, if the exposure to the distorted magnetic field happens for a limited amount of time, without any major orientation drift.
Please see the video below for a demonstration of the improved filter. An iron plate is used to distort the magnetic field. As soon as the sensor gets close to the metal surface the magnetic field vector starts changing direction deliberately. The color of the cube on the monitor turns red in case of the detection of a distorted magnetic field.
Lin, Professor Takanishi and me recently had quite a lively discussion about the question if and to which degree we should open-source the company’s motion analysis software. On the one hand I strongly voted for open-sourcing everything, to quickly make our company known and to support the open-source community. Lin and Prof. Takanishi on the other hand were worried about competitors re-using our code for their own products without giving us proper credits (and therefore violating the GPL). Obviously both sides have their pros and cons, so I thought it might be nice to ask that question to the community on Slashdot. Today the questions has been published. Check here to read the comments.
So far we used quite a small battery (80 mAh) to power the LPMS. This worked quite well for some time, but in the end we realized that continuous runtimes of about 1h are just not enough to do practical measurements. We therefore started experimenting with batteries with higher capacity. As you can see in the image below, we were able to prolong runtimes quite a bit, with luckily not having to compromise on size and weight of the sensor too much.
Rechargeable batteries with different sizes and run-times.
We are not quite ready release the complete specifications of these new types, but basically they will be energy optimized also on the software side and the battery will be exchangeable, so that the user can decide which size he prefers. Also for longer measurements, it might be handy to have a few spare batteries. We will sell additional batteries separately at a decent price.
This is our first Blog post, so I would like to keep you updated about a few things regarding LP. First I would like to introduce the place that we work at every day. As Lin and I both graduated from Takanishi Lab. at Waseda University, we have still good connections with the university and also work part-time as post-docs in the laboratory. LP-Research itself is headquatered in the Waseda Incubation Center.
The Waseda Incubation Center (WIC)
Our work as post-doc researchers we do at a place called TWins, which is a collaborative institution between Waseda University and Tokyo Women's Medical University.